Experimental investigations of application of the water-steam оzone-containing gaseous mixture for prophylaxis and treatment of respiratory infectious diseases

Objective. Determination of the virus-cidal and bacterio-cidal action of the ozone-containing steam-water mixture, which was obtained, using apparatus POS-1, simulated on viral models of transmissive gastroenteritis of pigs of the coronaviruses family and polyresistant clinical strains of bacterial cultures, as well as adjustment of optimal parameters of ozone in the gaseous mixture content, which do not cause pathological changes in the organism’s organs and systems. Materials and methods. Apparatus POS-1, created by collective of Scientific-Methodical Centre «Medical Innovation Technologies»», was applied for production of the ozone-containing gaseous mixture. Virusological investigations were conducted on the base of the Institute of Epidemiology and Infectious Diseases named after L. V, Gromashevskiy. As a working material the models of virus of the pigs transmissive gastroenteritis of the coronaviruses family were applied. The series of bacteriological and experimental investigations were conducted on the base of Shalimov National Institute of Surgery and Transplantology NAMS of Ukraine. Polyresistant cultures in concentration of 108 colony-creating units per 1 ml were applied for bacteriological investigations. The experiment was conducted on white rats to study the gaseous ozone-containing mixture affection on living biological tissues. Results. Virusological investigations have shown, that in the 20 minutes exposition and a contact with extracellular virus the infection titer have lowered in 100 000 times, and in a 30 minutes exposition - a complete deactivation of virus have had occurred. Bacteriological investigations have revealed the complete absence of the cultures development after their processing with the ozone-containing mixture during 20 min. The results of swimming tests and behavioral reactions in white rats of control and experimental groups did not differ. Histological investigations of the respiratory organs tissues as well as of spleen, thyroid gland, kidneys and suprarenal glands did not reveal pathological effects of the ozone-containing mixture. Conclusion. Parameters of the ozone generation and delivery in the gaseous mixture content were studied and optimally selected. Investigations of the ozone-containing mixture affection on a viral strain of the coronaviruses family, as well as bacteriological investigations on polyresistant bacterial cultures have had confirmed its pronounced virus-cidal and bactericidal properties. Application of the ozone-containing mixture do not cause any pathological changes in the living organism organs and systems. This gaseous mixture may be used for prevention and treatment of respiratory infectious diseases of viral and bacterial genesis.

The association of human astrovirus with extracellular vesicles facilitates cell infection and protects the virus from neutralizing antibodies

Viral gastroenteritis has a global distribution and represents a high risk for vulnerable population and children under 5 years because of acute diarrhea, fever and dehydration. Human astroviruses (HAstV) have been identified as the third most important cause of viral gastroenteritis in pediatric and immunocompromised patients. Furthermore, HAstV has been reported in biopsies taken from patients with encephalitis, meningitis and acute respiratory infection, yet it is not clear how the virus reaches these organs. In this work we tested the possibility that the released astrovirus particles could be associated with extracellular vesicles. Comparison between vesicles purified from astrovirus- and mock-infected cells showed that infection with HAstV Yuc8 enhances production of vesicles larger than 150 nm. These vesicles contain CD63 and Alix, two markers of vesicular structures. Some of the extracellular virus was found associated with vesicular membranes, and this association facilitates cell infection in the absence of trypsin activation and protects virions from neutralizing antibodies. Our findings suggest a new pathway for HAstV spread and might represent an explanation for the extraintestinal presence of some astrovirus strains.

Mathematical modeling of hepatitis C RNA replication, exosome secretion and virus release

Hepatitis C virus (HCV) causes acute hepatitis C and can lead to life-threatening complications if it becomes chronic. The HCV genome is a single plus strand of RNA. Its intracellular replication is a spatiotemporally coordinated process of RNA translation upon cell infection, RNA synthesis within a replication compartment, and virus particle production. While HCV is mainly transmitted via mature infectious virus particles, it has also been suggested that HCV-infected cells can secrete HCV RNA carrying exosomes that can infect cells in a receptor independent manner. In order to gain insight into these two routes of transmission, we developed a series of intracellular HCV replication models that include HCV RNA secretion and/or virus assembly and release. Fitting our models to in vitro data, in which cells were infected with HCV, suggests that initially most secreted HCV RNA derives from intracellular cytosolic plus-strand RNA, but subsequently secreted HCV RNA derives equally from the cytoplasm and the replication compartments. Furthermore, our model fits to the data suggest that the rate of virus assembly and release is limited by host cell resources. Including the effects of direct acting antivirals in our models, we found that in spite of decreasing intracellular HCV RNA and extracellular virus concentration, low level HCV RNA secretion may continue as long as intracellular RNA is available. This may possibly explain the presence of detectable levels of plasma HCV RNA at the end of treatment even in patients that ultimately attain a sustained virologic response.

Imaging-Based Reporter Systems to Define CVB-Induced Membrane Remodeling in Living Cells

Enteroviruses manipulate host membranes to form replication organelles, which concentrate viral and host factors to allow for efficient replication. However, this process has not been well-studied in living cells throughout the course of infection. To define the dynamic process of enterovirus membrane remodeling of major secretory pathway organelles, we have developed plasmid-based reporter systems that utilize viral protease-dependent release of a nuclear-localized fluorescent protein from the endoplasmic reticulum (ER) membrane during infection, while retaining organelle-specific fluorescent protein markers such as the ER and Golgi. This system thus allows for the monitoring of organelle-specific changes induced by infection in real-time. Using long-term time-lapse imaging of living cells infected with coxsackievirus B3 (CVB), we detected reporter translocation to the nucleus beginning ~4 h post-infection, which correlated with a loss of Golgi integrity and a collapse of the peripheral ER. Lastly, we applied our system to study the effects of a calcium channel inhibitor, 2APB, on virus-induced manipulation of host membranes. We found that 2APB treatment had no effect on the kinetics of infection or the percentage of infected cells. However, we observed aberrant ER structures in CVB-infected cells treated with 2APB and a significant decrease in viral-dependent cell lysis, which corresponded with a decrease in extracellular virus titers. Thus, our system provides a tractable platform to monitor the effects of inhibitors, gene silencing, and/or gene editing on viral manipulation of host membranes, which can help determine the mechanism of action for antivirals.

The Molluscum Contagiosum Gene MC021L Partially Compensates for the Loss of Its Vaccinia Virus Homolog, F13L

ABSTRACT Orthopoxviruses produce two antigenically distinct infectious enveloped virions termed intracellular mature virions and extracellular virions (EV). EV have an additional membrane compared to intracellular mature virions due to a wrapping process at the trans-Golgi network and are required for cell-to-cell spread and pathogenesis. Specific to the EV membrane are a number of proteins highly conserved among orthopoxviruses, including F13, which is required for the efficient wrapping of intracellular mature virions to produce EV and which plays a role in EV entry. The distantly related molluscipoxvirus, molluscum contagiosum virus, is predicted to encode several vaccinia virus homologs of EV-specific proteins, including the homolog of F13L, MC021L. To study the function of MC021, we replaced the F13L open reading frame in vaccinia virus with an epitope-tagged version of MC021L. The resulting virus (vMC021L-HA) had a small-plaque phenotype compared to vF13L-HA but larger than vΔF13L. The localization of MC021-HA was markedly different from that of F13-HA in infected cells, but MC021-HA was still incorporated in the EV membrane. Similar to F13-HA, MC021-HA was capable of interacting with both A33 and B5. Although MC021-HA expression did not fully restore plaque size, vMC021L-HA produced amounts of EV similar to those produced by vF13L-HA, suggesting that MC021 retained some of the functionality of F13. Further analysis revealed that EV produced from vMC021L-HA exhibit a marked reduction in target cell binding and an increase in dissolution, both of which correlated with a small-plaque phenotype. IMPORTANCE The vaccinia virus extracellular virion protein F13 is required for the production and release of infectious extracellular virus, which in turn is essential for the subsequent spread and pathogenesis of orthopoxviruses. Molluscum contagiosum virus infects millions of people worldwide each year, but it is unknown whether EV are produced during infection for spread. Molluscum contagiosum virus contains a homolog of F13L termed MC021L. To study the potential function of this homolog during infection, we utilized vaccinia virus as a surrogate and showed that a vaccinia virus expressing MC021L-HA in place of F13L-HA exhibits a small-plaque phenotype but produces similar levels of EV. These results suggest that MC021-HA can compensate for the loss of F13-HA by facilitating wrapping to produce EV and further delineates the dual role of F13 during infection.

Practical aspects on identification, cultivation and characteristics of varicella-zoster virus isolates

Until now, it has been considered that infectivity of the varicella-zoster virus (VZV) is closely related to target cell, and newly formed virus is not released into the culture medium. It is also known that it is hard to grow VZV in cell cultures, due to its slow replication rate and a limited range of sensitive cell cultures. In addition, VZV isolation depends on type of cell culture used, nature of clinical material, presence of viable virus and transport time. Objectives. To study production of infectious extracellular VZV in various cell cultures. Materials and methods. Eight cell cultures were used, including human embryonic diploid lung cells and human embryonic dermomuscular tissue (KM-27), as well as continuous human and monkey cell lines. Crusts detached from vesicular lesions were used as clinical isolates, which were placed into cryo-vials added with transport medium and transferred in liquid nitrogen. VZV infectivity was assessed in cell cultures by using hemo-adsorption assay with erythrocyte suspension isolated from guinea pig or human zero group blood and confirmed by indirect immunofluorescence with polyclonal sera from varicella or herpes zoster convalescents. Results. There were examined 27 clinical samples consisting of crusts from vesicular lesions isolated from patients with chickenpox, as well as one sample from 63-year old patient with exacerbated recurrent herpes zoster. Primary infection with clinical isolates was performed on diploid human lung embryo cells (HLEC) at low temperature. It was found that clinical samples collected within day 1–18 inclusive after the onset of skin eruption were able to induce cytopathic effects in HLEC cell monolayer such as cytolysis around dermal crusts. Specificity of cytopathic effect was confirmed by using real-time polymerase chain reaction (RT-PCR). Viral antigens were prepared on 7 cell lines infected with the laboratory strain Ellen VZV (USA) to assess the immune sera. A high anti-VZV specificity of mouse sera was detected by ELISA while all the lysates of infected cell lines were used as the solid-phase sorbent. In experiments on VZV reproduction demonstrated that extracellular virus was released into the culture medium starting from day 1 after infection of target cells, and infectivity of the virus-containing fluid ascends during further cultivation.

Defective HIV-1 proviruses produce viral proteins

HIV-1 proviruses persist in the CD4+ T cells of HIV-infected individuals despite years of combination antiretroviral therapy (cART) with suppression of HIV-1 RNA levels <40 copies/mL. Greater than 95% of these proviruses detected in circulating peripheral blood mononuclear cells (PBMCs) are referred to as “defective” by virtue of having large internal deletions and lethal genetic mutations. As these defective proviruses are unable to encode intact and replication-competent viruses, they have long been thought of as biologically irrelevant “graveyard” of viruses with little significance to HIV-1 pathogenesis. Contrary to this notion, we have recently demonstrated that these defective proviruses are not silent, are capable of transcribing novel unspliced forms of HIV-RNA transcripts with competent open reading frames (ORFs), and can be found in the peripheral blood CD4+ T cells of patients at all stages of HIV-1 infection. In the present study, by an approach of combining serial dilutions of CD4+ T cells and T cell–cloning technologies, we are able to demonstrate that defective proviruses that persist in HIV-infected individuals during suppressive cART are translationally competent and produce the HIV-1 Gag and Nef proteins. The HIV-RNA transcripts expressed from these defective proviruses may trigger an element of innate immunity. Likewise, the viral proteins coded in the defective proviruses may form extracellular virus-like particles and may trigger immune responses. The persistent production of HIV-1 proteins in the absence of viral replication helps explain persistent immune activation despite HIV-1 levels below detection, and also presents new challenges to HIV-1 eradication.

Vaccinia Virus Glycoproteins A33, A34, and B5 Form a Complex for Efficient Endoplasmic Reticulum to trans-Golgi Network Transport

ABSTRACT Orthopoxviruses produce two, antigenically distinct, infectious enveloped virions termed intracellular mature virions and extracellular virions. Extracellular virions are required for cell-to-cell spread and pathogenesis. Specific to the extracellular virion membrane, glycoproteins A33, A34, and B5 are highly conserved among orthopoxviruses and have roles during extracellular virion formation and subsequent infection. B5 is dependent on an interaction with either A33 or A34 for localization to the site of intracellular envelopment and incorporation into the envelope of released extracellular virions. In this report we show that an interaction between A33 and A34 can be detected in infected cells. Furthermore, we show that a three-protein complex between A33, A34, and B5 forms in the endoplasmic reticulum (ER) that disassociates post ER export. Finally, immunofluorescence reveals that coexpression of all three glycoproteins results in their localization to a juxtanuclear region that is presumably the site of intracellular envelopment. These results demonstrate the existence of two previously unidentified interactions: one between A33 and A34 and another simultaneous interaction between all three of the glycoproteins. Furthermore, these results indicate that interactions among A33, A34, and B5 are vital for proper intracellular trafficking and subcellular localization. IMPORTANCE The secondary intracellular envelopment of poxviruses at the trans-Golgi network to release infectious extracellular virus (EV) is essential for their spread and pathogenesis. Viral glycoproteins A33, A34, and B5 are critical for the efficient production of infectious EV and interactions among these proteins are important for their localization and incorporation into the outer extracellular virion membrane. We have uncovered a novel interaction between glycoproteins A33 and A34. Furthermore, we show that B5 can interact with the A33-A34 complex. Our analysis indicates that the three-protein complex has a role in ER exit and proper localization of the three glycoproteins to the intracellular site of wrapping. These results show that a complex set of interactions occur in the secretory pathway of infected cells to ensure proper glycoprotein trafficking and envelope content, which is important for the release of infectious poxvirus virions.

Fetal Calf Serum Exerts an Inhibitory Effect on Replication of Duck Hepatitis A Virus Genotype 1 in Duck Embryo Fibroblast Cells

Among the causative agents of duck viral hepatitis, duck hepatitis A virus genotype 1 (DHAV-1) is the most common virus reported in most outbreaks worldwide. How to propagate DHAV-1 in cell cultures efficiently remains a problem to be explored. Here, we aimed to test the effect of serum type on DHAV-1 replication in duck embryo fibroblast (DEF) cells. Comparative studies involved virus culture and passage, observation of cytopathic effect (CPE), virus quantification, and plaque formation assay. From the results of these investigations, we conclude that use of chicken serum (CS) in maintenance medium allows DHAV-1 to establish productive, cytocidal infection in DEF cells, whereas FCS exerts inhibitory effects on DHAV-1 replication, CPE development, and plaque formation. By using a neutralization test, we found that the direct action of FCS on virions is likely to play a key role in inhibiting DHAV-1 replication in DEF cells. Mechanism analyses revealed that FCS inhibits DHAV-1 replication at virus adsorption and reduces extracellular virus yields. The present work may shed light on a new perspective for antiviral agent development, and have provided a virus–host cell system for further studies on molecular mechanism involved DHAV-1 replication and pathogenesis.

Coxsackievirus B Escapes the Infected Cell in Ejected Mitophagosomes

ABSTRACT Coxsackievirus B (CVB) is a common enterovirus that can cause various systemic inflammatory diseases. Because CVB lacks an envelope, it has been thought to be inherently cytolytic, wherein CVB can escape from the infected host cell only by causing it to rupture. In recent years, however, we and others have observed that various naked viruses, such as CVB, can trigger the release of infectious extracellular microvesicles (EMVs) that contain viral material. This mode of cellular escape has been suggested to allow the virus to be masked from the adaptive immune system. Additionally, we have previously reported that these viral EMVs have LC3, suggesting that they originated from autophagosomes. We now report that CVB-infected cells trigger DRP1-mediated fragmentation of mitochondria, which is a precursor to autophagic mitochondrial elimination (mitophagy). However, rather than being degraded by lysosomes, mitochondrion-containing autophagosomes are released from the cell. We believe that CVB localizes to mitochondria, induces mitophagy, and subsequently disseminates from the cell in an autophagosome-bound mitochondrion-virus complex. Suppressing the mitophagy pathway in HL-1 cardiomyocytes with either small interfering RNA (siRNA) or Mdivi-1 caused marked reduction in virus production. The findings in this study suggest that CVB subverts mitophagy machinery to support viral dissemination in released EMVs. IMPORTANCE Coxsackievirus B (CVB) can cause a number of life-threatening inflammatory diseases. Though CVB is well known to disseminate via cytolysis, recent reports have revealed a second pathway in which CVB can become encapsulated in host membrane components to escape the cell in an exosome-like particle. Here we report that these membrane-bound structures derive from mitophagosomes. Blocking various steps in the mitophagy pathway reduced levels of intracellular and extracellular virus. Not only does this study reveal a novel mechanism of picornaviral dissemination, but also it sheds light on new therapeutic targets to treat CVB and potentially other picornaviral infections.